Failure Mode and Effect Analysis Power Plant Boiler
الموضوعات :Guntur Pratama Putra 1 , Humiras Hardi Purba 2
1 - Master of Industrial Engineering, MercuBuana University,Jakarta, Indonesia
2 - Master of Industrial Engineering, MercuBuana University,Jakarta, Indonesia
الکلمات المفتاحية: Boiler, PowerPlant, Thermal Power, Failure mode and effect analysis,
ملخص المقالة :
The current electricity demand is increasing, and now the government has involved third parties in the implementation of electricity so that investors compete in building infrastructure in order to apply electricity. Thermal power is one source that has a fast break event point compared to other resources that more interested investors even with all forms of pollution caused. A form of heat power using a vapor pressure is fired into the turbine so that it will cause a rotating force that will turn the generator into an electric generator. thermal power has the ability to generate electricity large, but if there is a failure in operation, then the burden will quickly lose power sources that can cripple production activities.FMEA is one of the most widely used tools in the industry to analyze the root cause of the system so that the system is protected from small and large damage and can disrupt the stability of the industrial operating system. The reliability of the machine must always be maintained so that with this method it is expected to help the power service providers to maintain the availability of its services.With the implementation of FMEA, we get an overview of the steps to be taken for the future so that the reliability of a steam generator boiler system can be improved
Afefy, I. H. (2010). Reliability-Centered Maintenance Methodology and Application: A Case Study. Engineering, 2(11), 863–873. https://doi.org/10.4236/engineering.2010.211109
Afefy, I. H. (2015). Hazard Analysis and Risk Assessments for Industrial Processes Using FMEA and Bow-Tie Methodologies, 14(4), 379–391.
Al-khafaji, S. K. H. (2005). Design of a Programmable System for Failure Modes and Effect Analysis of Steam-Power Plant Based on the Fault Tree Analysis, 1(2), 64–85.
Ambekar, S., Edlabadkar, A., & Shrouty, V. (2013). A Review: Implementation of Failure Mode and Effect Analysis. Ijeit.Com, 2(8), 37–41. Retrieved from http://ijeit.com/vol 2/Issue 8/IJEIT1412201302_07.pdf
Carazas, F. J. G., Salazar, C. H., & Souza, G. F. M. (2011). Availability analysis of heat recovery steam generators used in thermal power plants. Energy, 36(6), 3855–3870. https://doi.org/10.1016/j.energy.2010.10.003
Chikhale, S. S., & Barik, M. K. (2015). Failure Mode and Effect Analysis on Base Frame – Case Study. Journal of Emerging Technologies and Innovative Research, 2(4), 1283–1288.
Dobrivoje, Ć. (2011). Fmea in product development phase. Fmea in Product Development Phase, 679–686.
Lipol, L. S., & Haq, J. (2011). Risk analysis method : FMEA / FMECA in the organizations . International Journal of Basic & Applied Sciences, 11(5).
Management, N. (2013). Simple approach to failure modes using a maintenance organisation and management software (1) Marcelo Batista , José Fernandes (1) and Alexandre Veríssimo (1), (1).
Mutlu, N. G., Altuntas, S., & Türkdoğan, İ. (2016). Failure modes and effects analysis for cogeneration unit in a wastewater treatment plant Failure modes and effects analysis for cogeneration unit in a wastewater treatment plant, (September), 0–7.
Nagar, V. (2013). Boiler Efficiency Improvement through Analysis of Losses. International Journal for Scientific Research & Development, 1(3), 1–5.
Othman, H., Purbolaksono, J., & Ahmad, B. (2009). Failure investigation on deformed superheater tubes. Engineering Failure Analysis, 16(1), 329–339. https://doi.org/10.1016/j.engfailanal.2008.05.023
Popović, V., Vasić, B., & Petrović, M. (2010). The possibility for FMEA method improvement and its implementation into bus life cycle. Strojniski Vestnik/Journal of Mechanical Engineering, 56(3), 1–7.
Purbolaksono, J., Ahmad, J., Beng, L. C., Rashid, A. Z., Khinani, A., & Ali, A. A. (2010). Failure analysis on a primary superheater tube of a power plant. Engineering Failure Analysis, 17(1), 158–167. https://doi.org/10.1016/j.engfailanal.2009.04.017
Puspitasari, N. B., & Martanto, A. (2014). Penggunaan FMEA dalam Mengidentifikasi Resiko Kegagalan Proses Produksi Sarung ATM (Alat Tenun Mesin) (Studi Kasus PT ASAPUTEX Jaya Tegal). J@TI Undip, IX(2), 93–98.
Rakesh, R., Jos, B. C., & Mathew, G. (2013). FMEA Analysis for Reducing Breakdowns of a Sub System in the Life Care Product Manufacturing Industry. International Journal of Engineering Science and Innovative Technology, 2(2), 218–225.
S. Parsana, T., & T. Patel, M. (2014). A Case Study: A Process FMEA Tool to Enhance Quality and Efficiency of Manufacturing Industry. Bonfring International Journal of Industrial Engineering and Management Science, 4(3), 145–152. https://doi.org/10.9756/BIJIEMS.10350
Sellappan, N., & Palanikumar, K. (2013). Modified Prioritization Methodology for Risk Priority Number in Failure Mode and Effects Analysis. International Journal of Applied Science and Technology, 3(4), 27–36.
Sharma, K. D., & Srivastava, S. (2016). Failure Mode and Effect Analysis ( FMEA ) for Enhancing Reliability of Water Tube Boiler in Thermal Power Plant, 8(2).
Shivakumar, K. M., Hanumantharaya, R., & A, M. U. M. K. (2015). Implementation of FMEA in Injection Moulding Process, 22(5), 230–235.
Tomašková, M. (1929). Fmea-Analysis of Restricted Pressure Device for, (508), 46–54.